Laser drilling methods of shallow-angled holes

ABSTRACT

A method for drilling a shallow-angled hole through a thermal barrier coated component includes a step of applying a pulse laser beam to drill a section of the hole substantially within a thermal barrier coating of the component in a direction substantially perpendicular to a top surface of the component. A further step is conducted to apply the pulse laser beam to further drill through a base metal of the component to complete the formation of the hole extending through the component.

TECHNICAL FIELD

The described subject matter relates generally to laser drilling, andmore particularly to providing shallow-angled holes in coatedcomponents.

BACKGROUND OF THE ART

Combustors of gas turbine engines are subjected to high temperatures andeffusion holes can be used to direct air to cool combustor componentssuch as combustor liner, dome and heat shield. Effusion holes extendthrough the component at a shallow angle with respect to the surface ofthe component, for efficiently cooling without risking a reduction incombustion temperature. Laser beam drilling of effusion holes incombustor components has confronted challenges. A combustor component iscoated with a thermal barrier coating (TBC). Although a TBC layer isabout 30% or less of, for example a heat shield thickness, it consumesmore than 60% of the laser drilling energy, due to TBC properties suchas heat resistance and poor thermal conductivity. Laser pulse energy isutilized to enable drilling through the TBC layer, but that laser pulseenergy is too high for drilling through the base metal under the TBC,which causes excessive recast layer. The shallow angle of the effusionholes increases the distance which the laser beam has to drill throughand increases the laser strike area on the component surface. Thiscauses the intensity of the laser pulse to dissipate. Furthermore,shallow holes with an angle to the surface equal to or less than 20degrees, may cause relatively long cracks at the interface between theTBC and the base metal. Crack length and the area subject to cracksincrease as hole angle to surface decreases. Coating cracks are the maincontributor to TBC spallation and chipping which risk part scrap orreduced part life in gas turbine engines.

Accordingly, there is a need to provide improvements.

SUMMARY

In one aspect, the described subject matter provides a method forproviding a hole through metal component having a base metal and athermal barrier coating applied to the base metal to form a top surfaceof the component, the hole having a central axis extending at an angleof 20 degrees or less with respect to the top surface, the methodcomprising a) applying a pulse laser beam perpendicular with respect tothe top surface of the component to drill a hole substantiallypenetrating only the thermal barrier coating; and then b) applying thepulse laser beam at said angle with respect to the top surface andaligned with the hole drilled in step (a) to drill through the thermalbarrier coating and base metal.

In another aspect, the described subject matter provides a method forproviding a plurality of holes distributed over a top surface of aturbine combustor component, the component including a base metal and athermal barrier coating applied to the base metal with a bond coat, thethermal barrier coating forming the top surface of the component, eachof the holes having a central axis extending at an angle of 20 degreesor less with respect to the top surface, and each of the holes extendingthrough the thermal barrier coating, bond coat and base metal of thecomponent and having a circular cross section, the method comprising a)applying a pulse laser beam in a perpendicular direction with respect tothe top surface of the component to remove material of the thermalbarrier coating within a final perimeter of the one hole, to therebypartially drill a section of one of the holes free of extending into thebase metal; b) applying the pulse laser beam through the partiallydrilled section of the one hole to drill through the thermal barriercoating, bond coat and base metal at said angle with respect to the topsurface in order to complete formation of the one hole extending throughthe component; and c) repeating steps (a) and (b) to complete theremaining holes extending through the components.

Further details of these and other aspects of the described subjectmatter will be apparent from the detailed description and drawingsincluded below.

BRIEF DESCRIPTION OF THE DRAWINGS

Reference is now made to the accompanying drawings depicting aspects ofthe described subject matter, in which:

FIG. 1 is a schematic cross-sectional view of a turbofan gas turbineengine as an example illustrating an application of the describedsubject matter;

FIG. 2 is a schematic cross-sectional view of a combustor componenthaving shallow-angled effusion holes (only one shown), used in the gasturbine engine of FIG. 1, illustrating potential spallation which isminimized in the hole drilling procedure according to the describedembodiments;

FIG. 3 is a schematic cross-sectional view of a hole drilling procedure,showing a step of drilling a section of the hole within a thermalbarrier coating of the combustor component;

FIG. 4A is a schematic illustration of the trepanning concept used inthe drilling step shown in FIG, showing a cross-section of the holeperpendicular to a central axis of the hole;

FIG. 4B is a schematic illustration of the trepanning concept used inthe drilling step shown in FIG. 3, showing a boundary of the hole on atop surface of the component through which the hole extends, which isnot in proportion to the illustration of FIG. 4A;

FIG. 5 is a schematic cross-sectional view of the combustor component ofFIG. 3 in the hole drilling procedure, showing a further step ofdrilling through the base metal of component;

FIG. 6 is a schematic cross-sectional view of a combustor component in ahole drilling procedure according to another embodiment, showing a stepof perpendicularly drilling into the thermal barrier coating of thecomponent, to partially form a section of the hole in the thermalbarrier coating;

FIG. 7 is a schematic cross-sectional view of a combustor component in ahole drilling procedure according to another embodiment, showingdrilling through the hole with a pulse laser beam having different lasersettings for drilling through the respective thermal barrier coating andbase metal;

FIG. 8 is a graphic illustration, showing the laser pulses used in thedrilling procedure of FIG. 7;

FIG. 9 is a schematic cross-sectional view of a combustor component in amultiple-hole drilling procedure according to a further embodiment,showing a drilling sequence in the various locations of the holes, onelaser shot at a time in each hole;

FIG. 10 is a schematic cross-sectional view of a base metal of acombustor component in a hole drilling procedure before a thermalbarrier coating is attached thereon, according to a further embodiment;

FIG. 11 is a cross-sectional view of the base metal of the component ofFIG. 10, showing the thermal barrier coating attached to the base metalafter a section of the hole is completed through the base metal;

FIG. 12 is a schematic cross-sectional view of the combustor componentof FIG. 11 in a further hole drilling stage, showing a step of drillingthe thermal barrier coating to complete the hole extending through thecomponent;

FIG. 13 is a schematic cross-sectional view of a base metal of acombustor component coated with a thin bond coat in a hole drillingprocedure, before a thermal barrier coating is attached, according to afurther embodiment;

FIG. 14 is a schematic cross-sectional view of the base metal of thecombustor component coated with the bond coat of FIG. 13, showing athermal barrier coating attached to the bond coat on the base metal ofthe component after a section of the hole has been formed in the bondcoat and the base metal of the component;

FIG. 15 is a schematic cross-sectional view of the combustor componentof FIG. 14 in a further step of drilling through the thermal barriercoating to complete the hole extending through the component;

FIG. 16 is a schematic cross-sectional view of a combustor component ina hole drilling procedure according to a further embodiment, showing afocal point of the pulse laser beam being continuously moved into thecombustor component as each consecutive shot of the pulse laser beam isapplied to the combustor component;

FIG. 17 is a schematic cross-sectional view of a combustor component ina hole drilling procedure according to a further embodiment, showingapplication of an assist gas jet during the laser drilling procedure;and

FIG. 18 is a graphic illustration, showing a gas jet pressure controlprinciple used in the embodiment of FIG. 17.

Further details of these and other aspects of the described subjectmatter will be apparent from the detailed description and drawingsincluded below.

It will be noted that throughout the appended drawings, like featuresare identified by like reference numerals.

DETAILED DESCRIPTION

FIG. 1 illustrates a gas turbine engine as an example of the applicationof the described subject matter, which includes a housing or nacelle 10,a core casing 13, a low pressure spool assembly seen generally at 12which includes a fan assembly 14, a low pressure compressor assembly 16and a low pressure turbine assembly 18 and a high pressure spoolassembly seen generally at 20 which includes a high pressure compressorassembly 22 and a high pressure turbine assembly 24. The core casing 13surrounds the low and high pressure spool assemblies 12 an 20 in orderto define a main fluid path (not numbered) therethrough including acombustor 26.

The combustor 26 includes various combustor components such as liners,heat shields, etc. One combustor component 28 is shown in FIG. 2 whichincludes a base metal 30, as a substrate, coated with a thermal barriercoating (TBC) 34 attached thereto. The thermal barrier coating 34 andthe base metal 30 are secured together, for example by a layer of bondcoat (BC) 32 disposed therebetween. Effusion holes are distributed overan area of the combustor component 28. An example of one effusion hole36 shown in the combustor component 28 is cylindrical and extendsthrough the combustor component 28 including the thermal barrier coating34, bond coat 32 and the base metal 30. The effusion hole 36 has acentral axis 38 disposed at a non-zero shallow-angle of, for example 20degrees or less with respect to a top surface 40 formed by the thermalbarrier coating 34.

The effusion hole 36 may be formed by applying a pulse laser beam energyto the combustor component 28. As previously discussed, due to theshallow angle of the effusion holes 36 relative to the to the topsurface 40 and due to the different material properties of therespective thermal barrier coating 34, bond coat 32 and the base metal30, cracks (not numbered) may occur at the interface between the thermalbarrier coating 34 and the bond coat 32 or at the interface between thebond coat 32 and the base metal 30 during a pulse laser beam drillingprocedure, thereby causing TBC-BC spallation or BC-substrate spallationas shown in FIG. 2. However, the potential risks of causing cracks atthe layer's interface (not numbered) during hole drilling, is minimizedor eliminated in drilling procedures according to various embodimentsdescribed hereinafter.

Similar components and features in various embodiments indicated bysimilar numeral references will not be redundantly described.

Referring to FIGS. 3-5, an effusion hole 37 is being drilled in thecombustor component 28, extending through the thermal barrier coating 34and the base metal 30 (the bond coat therebetween is very thin and notshown). The central axis 38 of the effusion hole 37 is disposed at anangle of 20 degrees or less with respect to the top surface 40 and thehole 37 is in a truncated conical profile with a diameter diminishing asthe hole 37 extends from the top surface 40 to an under surface 41 ofthe component 28, formed by the base metal 30. This truncated conicalprofiled hole 37 is provided as an example to illustrate variousembodiment of laser hole drilling which are also applicable tocylindrical or other profiled holes.

Referring to FIG. 5, it is noted that hole 37 is angled and shaped suchthat, in cross-section, intersects the top surface 40 on one side withan acute angle (not indicated) between the side of hole and the topsurface 40 and an obtuse angle (not indicated) opposite thereto, andintersects the bottom surface 41 on one side with an obtuse angle (notindicated) between the side of hole and the bottom surface 41 and anacute angle (not indicated) opposite thereto.

In accordance with one embodiment, the hole drilling procedure includesa first step of applying a pulse laser beam 42 to drill a section 46 ofthe hole 37 substantially through only the thermal barrier coating 34.The laser drilling of the section 46 is completed in a trepanningconcept to interpolate the laser beam within a final perimeter 48 of thehole 37.

The effusion hole 37 may be in a truncated conical shape and thereforethe final perimeter 48 in any cross-section thereof which isperpendicular to the central axis 38 of the hole 37, is circular asshown in FIG. 4A. However, a boundary 48 a of the final perimeter 48 ofthe effusion hole 37 on the top surface 40 of the combustor component 28is elliptical, as shown in FIG. 4B. A central axis 44 of the pulse laserbeam 42 is disposed parallel to the central axis 38 of the effusion hole37, that is, at the angle of the central axis 38 of the hole 37 withrespect to the top surface 40. A laser drilling step for completing thesection 46 of the hole 37 within the thermal barrier layer 34 isconducted by moving the central axis 44 of the pulse laser beam 42 in acircular motion 52 to confine the pulse laser beam 42 within theboundaries of the final perimeter 48 of the effusion hole 37, therebyinterpolating a target spot 50 of the laser beam 42 along the finalperimeter 48 of the hole 37 to complete the formation of the section 46of the hole 37 through the thermal barrier coating 34. Nevertheless, thecircular motion 52 of the central axis 44 makes an elliptical track 52 aon the top surface 40 of the combustor component 28, as shown in FIG.4B, thereby interpolating an elliptical target spot 50 a along theelliptical boundary 48 a of the hole 37.

The laser beam target spot 50 at this step may be set with a spotdiameter smaller than the diameter of the final perimeter 48 of theeffusion hole 37 at the cross-section of the hole 37, for example, aminimum diameter of the hole 37. When the target spot is relativelysmall as shown in FIG. 4B, the central axis 44 of the pulse laser beam42 must be moved within the boundary 48 a, following various routes, forexample as indicated by arrow 52 b, in order to complete the formationof the section 46 of the hole 37.

After the drilling of the section 46 of the hole 37 within the thermalbarrier coating 34 is completed, the pulse laser beam 42 is furtherapplied to drill through the base metal 30, for example, by disposingthe central axis 44 of the pulse laser beam 42 at the required angle andapplying shots of the pulse laser beam 42 through the completed section42 of the hole 37 to strike the base metal 30 until the hole 37 extendsthrough the entire component 28. The pulse laser beam 42 used in thisembodiment may be set with a first pulse rate for drilling through thethermal barrier coating 34 as shown in FIG. 3 and then re-set with asecond pulse rate for drilling through the base metal 30 as shown inFIG. 5. The first pulse rate may be higher than the second pulse rate.In this embodiment, the pulse laser beam 42 may also be set with a firstpulse energy level for drilling through the thermal barrier coating 34as shown in FIG. 3 and then re-set with a second pulse energy level fordrilling through the base metal 30 as shown in FIG. 5. The first pulseenergy level may be lower than the second pulse energy level.

The drilling steps shown in FIGS. 3-5 may be repeated at variouslocations over the top surface 40 of the combustor component 28 tocomplete the formation of other effusion holes in the combustorcomponent 28.

The above-description does not mention a particular step of drillingthrough a very thin bond coat layer (not indicated in FIGS. 3-5) betweenthe thermal barrier coating 34 and the base metal 30. In practice, thestep of drilling through this thin bond coat may be included information of the section 46. In such a case, the trepanning formation ofthe section 46 of the hole 37 extends through both the thermal barriercoating 34 and an underlying thin bond coat but not into the base metal30. Alternatively, drilling through the thin bond coat may beincorporated with the step of drilling through the base metal 30 afterthe section 46 of the hole 37 is formed within the thermal barriercoating 34.

The trepanning concept used in the hole drilling according to the aboveembodiment may also be applicable to a hole having a non-circularcross-section. The pulse laser beam 42 may have a target spot 50 or 50 ahaving a size smaller than a minimum cross-sectional dimension of thehole and is moved to allow the target spot 50 or 50 a of the laser beam42 to move within and along the boundaries of the final perimeter 48 ofthe effusion hole 37. In such a case, the hole will not be a circle asshown in FIG. 4A but may have a non-circular shape. The boundary of thefinal perimeter of the hole on the top surface 40 of the component 28,will not be elliptical as shown in FIG. 4B, but in a closed loop in anyshape. The central axis 44 of the pulse laser beam 42 will be movedtherefore in a closed loop (not shown) corresponding to and within theboundary (in any shape) of the final perimeter 48 of the hole 37.

FIG. 6 shows a combustor component similar to that of FIGS. 3 and 5, ina hole drilling procedure according to another embodiment. Instead ofdrilling through the thermal barrier coating 34 in a trepanning conceptas shown in FIG. 3, the step of drilling through only the thermalbarrier coating 34 according to this embodiment is conducted by drillingin a perpendicular direction with respect to the top surface 40 of thecombustor component 28 in order to remove material of the thermalbarrier coating 34 within the boundaries of the final perimeter 48 ofthe effusion hole 37. This drilling in the perpendicular direction maybe conducted one or more times at different locations within a boundaryof the final perimeter 48 of the effusion hole 37 on the top surface 40of the combustor component 28, each perpendicular drilling is conductedto a depth not greater than a thickness of the thermal barrier coatingor not greater than a sum of the thickness of the thermal barriercoating 34 and a bond coat (not indicated) attached to the under surfaceof the thermal barrier coating 34. It should be understood that thedepth of each perpendicular drilling in the different locations may varyin order to prevent extending beyond the final perimeter 48 of theeffusion hole 37, as shown in FIG. 6.

The perpendicular drilling however, may not be enabled to remove all ofthe thermal barrier coating material within the boundaries of the finalperimeter 48 of the hole and thus the perpendicular drilling procedureresults in a partial formation of the section 46 extending through thethermal barrier coating 34, or through both the thermal barrier coating34 the thin bond coat, leaving residual coating material within thefinal perimeter 48 of the effusion hole 37. The residual coatingmaterial within the final perimeter 48 of the effusion hole 37 isremoved in a further step by applying the pulse laser beam 32 at theangle of the hole, through the partially completed section 48 of theeffusion hole 37 to drill through the thermal barrier coating 34, thethin bond coat and the base metal 30 in order to complete formation ofthe effusion hole 37 extending through the entire combustor component28. This step is similar to the step in the previous embodiment withreference to FIG. 5 and will not be repeated in detail.

It should be understood that perpendicular drilling through the thermalbarrier coating 34 removes relatively more material of the thermalmaterial coating 34 and leaves less residual material within the finalperimeter 48 of the effusion hole 37 if the laser beam 42 is set with atarget spot having a relatively smaller size and if the laser beam 42 isapplied to relatively more drilling locations within the boundary of thefinal perimeter 48 on the top surface 40 of the combustor component 28.Therefore, it may be desirable to use a pulse laser beam 42 with atarget spot having a size smaller than, for example a diameter of theeffusion hole 37 in any completely circular cross-section perpendicularto the central axis 38 of the hole, or smaller than a minimumcross-sectional dimension of the effusion hole 27 in the case that thecross-sectional shape of the effusion hole 37 is not circular.

Similar to the previous embodiment, the laser beam 42 used in thisembodiment may also have different settings for drilling through thedifferent layers of the combustor component 28, which will not berepeated herein.

Referring to FIGS. 7 and 8, another embodiment of the hole drillingprocedure is described. The steps of drilling through the respectivethermal barrier coating 34 and base metal 30 in this embodiment may notnecessarily change drilling methods and therefore may be conducted inone method, for example by disposing the central axis 44 of the pulselaser beam 42 at the shallow angle of the effusion hole 37 relative tothe top surface 40 and applying shots of the pulse laser beam 42 tostrike the thermal barrier coating 34 and then the base metal 30 inorder to complete formation of the hole extending through the combustorcomponent 28. Nevertheless, the settings of the pulse laser beam 42differ between drilling through the respective thermal barrier coating34 and drilling through the base metal 30.

The pulse laser beam 42 is set with a first pulse frequency rate and afirst pulse energy level to drill a section of the effusion hole 37through the thermal barrier coating 34 only. The pulse laser beam 42 isthen re-set with a second pulse frequency rate and a second pulse energylevel to drill through the base metal 30 in order to complete formationof the effusion hole 37 extending through the combustor component 28.The first pulse frequency rate is higher than the second pulse frequencyrate and the first pulse energy level is lower than the second pulseenergy level.

Drilling through a thin bond coat (not indicated in FIG. 7) between thethermal barrier coating 34 and the base material 30 may be conductedtogether with the step of drilling through the thermal barrier coating34 or with the step of drilling through the base metal 30.

It should be understood that the principle of different laser settingssuitable for different materials of the thermal barrier coating and basemetal may be combined with different laser drilling methods for drillingthrough the respective thermal barrier coating 34 and base metal 30.Examples of such combinations are described above with reference topreviously described embodiments. Such combinations will be applicablein further embodiments described hereinafter.

The pulses of the pulse laser beam 42 which has the relatively highpulse frequency rate and low pulse energy level, is shown in solid linesin FIG. 8 and in comparison, the pulses of the pulse laser beam 42 whichhas the relatively low pulse frequency rate and higher pulse energylevel, is shown in broken lines in FIG. 8. The relatively high pulsefrequency rate as shown in the solid line, may be in a range between 50Hz and 100 Hz.

Referring to FIG. 9, the combustor component 28 is shown in a multiplehole drilling procedure according to a further embodiment. As previouslydescribed, a combustor component such as a liner, heat shield, etc.includes a plurality of effusion holes 37, for example four effusionholes 37 are shown in FIG. 9. In the previously described embodiments,only one of the effusion holes in the combustor component 28 is shown.It should be understood that the procedures of the previously describedembodiments are conducted by completing drilling of one effusion hole 37before drilling of another effusion hole 37 is begun. Therefore, theformation of the respective effusion holes 37 in a single combustorcomponent 28 is achieved one after another.

The multiple hole drilling procedure according to this embodiment ishowever conducted by applying a single shot of the pulse laser beam 42to strike the thermal barrier coating 34 once a time at each location ofthe effusion holes 37 in a selected sequence, for example as shown bythe arrows in FIG. 9, thereby removing a volume of the coating materialat each location of the effusion holes 37 until a first round of singleshots of the pulse laser beam 42 to the thermal barrier coating 34 overevery location of the effusion holes 37 is completed. A second round ofsingle shots of the laser beam 42 is then applied to each location ofthe effusion holes 37 in a sequence which may be the same or differentfrom the sequence of the first round of the single shots of the pulselaser beam 42, to strike the thermal barrier coating 34 within theboundaries of the final perimeter 48 of each effusion hole 37 beingdrilled. After a number of rounds of single shots of the pulse laserbeam 42 to the thermal barrier coating 34 in each location of theeffusion holes 37, a section 46 of each of the effusion holes 37 hasbeen at least partially drilled through the thermal bather coating 34 toexpose the bond coat and/or base metal 30. These steps are then repeatedto drill deeper into the materials of the combustor component 28including the base metal 30, within the boundaries of the finalperimeters 48 of the respective effusion holes 37 being drilled, untilformation of all the effusion holes 37 is completed.

In contrast to the hole drilling procedures of previous embodiments inwhich the formation of a plurality of effusion holes 37 in the combustorcomponent 28 is completed by completing the drilling of one hole beforebeginning the drilling of another hole, the completion of all of theeffusion holes 37 in the combustor component 28 in this embodiment iscompleted when the final round of single shots of the pulse laser beam42 to every location of the effusion holes 37, is completed. Therefore,the formation of all the respective effusion holes 37 in the combustorcomponent 28 is completed at substantially the same time.

According to this embodiment, completion of each effusion hole 37 takesmuch longer time in contrast to the time for completion of each effusionhole 37 in the previous embodiments, and the laser beam 42 does notimmediately follow a previous shot of the pulse laser beam 42 applied tothe same location of the effusion hole 37. This allows cooling of thecombustor component material in a local area around each effusion hole37, before the next laser shot (in the next round of laser beam shots)is applied to the same effusion hole 37. It also improves the heatgradient across the combustor component which reduces the chances ofcoating cracks. This may improve the formation quality of the effusionholes being drilled and may allow use of a higher pulse energy level ofthe laser beam because of the increased cooling time between laser beamshots in the same hole and the improved heat gradient, resulting in amore efficient drilling process.

Optionally, this embodiment can be combined with the previous describedembodiment illustrated in FIGS. 7 and 8 to set the pulse laser beam 42with the relatively high pulse frequency rate and relatively low pulseenergy level as shown by solid lines in FIG. 8, to be used in a fewinitial rounds of the single shots of the pulse laser beam to drillthrough the thermal barrier coating 34 and/or bond coat (not indicatedin FIG. 9) in respective locations of the effusion holes 37. The pulselaser beam can then be reset with the relatively low pulse frequencyrate and relatively high pulse laser energy levels as shown by brokenlines in FIG. 8, to be used in following rounds of the single shots ofthe pulse laser beams one shot a time to the base metal 30 of theeffusion holes 37.

Referring to FIGS. 10-12, the formation of a plurality of shallow angledeffusion holes 37 (only one shown) distributed over the top surface 40of the combustor component 28 according to this embodiment, begins withproviding the base metal 30 in an uncoated condition as shown in FIG.10. The pulse laser beam 42 is applied at the desired angle toindividual locations of the respective effusion holes 37 in the basemetal 30 in order to pre-drill a section of the respective effusionholes 37 through the uncoated base metal 30. The next step is to attachthe thermal barrier coating 34 onto the top surface (not numbered) ofthe uncoated base metal 38 with the bond coat (not indicated) disposedtherebetween in order to secure the thermal barrier coating 34 and thebase metal 30 together, as shown in FIG. 11. Therefore, the thermalbarrier coating 34 forms the top surface 40 of the combustor component28. The bond coat between the thermal barrier coating 34 and the basemetal 30 may or may not cover the pre-drilled section of the effusionholes 37 in the base metal 30. The bond coat may be applied to the topsurface of the base metal 30 or may be applied to an under face of thethermal barrier coating 34, after pre-drilling of the section of therespective effusion holes 37 through the base metal 30 is completed, butimmediately before attachment of the thermal barrier coating 34 to thebase metal 30.

The last step of this embodiment as illustrated in FIG. 12, is to applythe pulse laser beam 42 at the angle of the effusion holes 37 to variouslocations in the thermal barrier coating 34 in order to drill throughthe thermal barrier coating 34 and the bond coat into the pre-drilledsections of the respective effusion holes 37, thereby reopening thepre-drilled sections of the hole 37 and completing formation of theeffusion holes 37 extending through the combustor component 28.

This embodiment may be combined in various ways with the previouslydescribed embodiments. For example, different settings of the pulsefrequency rate and pulse energy level may be used for the respectivepre-drilling step of drilling through the uncoated base metal 30 and forthe final drilling step of drilling through the thermal barrier coating34. Different drilling methods may also be applied to the respectivepre-drilling step and the final drilling step, such as drilling in atrepanning concept, or applying a single shot of the pulse laser beam 42in each location of the effusion holes 37, in repeated round of laserbeam shots.

FIGS. 13-15 show an embodiment similar to the previously describedembodiment as shown in FIGS. 10-12. The difference between the twoembodiments lies in that the pre-drilling step begins with providing thebase metal 30 with a surface coated with the bond coat 32 as shown inFIG. 13, rather than the uncoated base metal 30 in FIG. 10. Therefore,the pulse laser beam 42 in this embodiment is applied at the desiredangle in various locations of the effusion holes 37 to the bond coat 32covering a surface (not numbered) of the base metal 30, to pre-drill thesection (not numbered) of the respective effusion holes 37 extendingthrough the bond coat 32 and the base metal 30 as shown in FIG. 13. Thethermal barrier coating 34 is then attached to the surface of the basemetal 30 covered by the bond coat 32, as shown in FIG. 14. The finaldrilling step is to apply the pulse laser beam 42 at the angle of theeffusion holes 37 to drill through the thermal barrier coating 34 atvarious locations in the thermal barrier coating 34 into the pre-drilledsections of the respective effusion holes 37 in the bond coat 32 andbase metal 30, thereby re-opening the pre-drilled sections of therespective effusion holes 37 and completing formation of the effusionholes 37 extending through the combustor component 28, as shown in FIG.15.

It should be noted that the attachment of the thermal barrier coating 34to the uncoated base metal 30 or to the surface of the base metal 30covered by the bond coat 32 in these two embodiments, should beconducted only after the pre-drilled sections of all the diffusion holes37 through the uncoated base metal 30 or through the bond coat 32 andbase metal 30 of the combustor component 28 are completed.

Optionally, a cleaning step may be desirable before attachment of thethermal barrier coating 34 to the uncoated base metal 30 or to thesurface of the base metal 30 covered by the bond coat 32 in these twoembodiments, in order to provide a clean surface of the uncoated basemetal 30 or the coated base metal 30 after the pre-drilling procedure,in order to improve the quality of attachment of the thermal barriercoating 34 to the uncoated base metal 30 or the coated base metal 30.The cleaning step may be conducted for example, by using pressurized gasjets which may be available in a laser drilling procedure, as will befurther described hereinafter.

It should be noted that after attachment of the thermal barrier coating34 to the uncoated or coated base metal 30, the pre-drilled sections ofthe respective effusion holes 37 are not visible from the side of thecombustor component 28 attached with the thermal barrier coating.Optionally, a step of probing and/or scanning the combustor component 28which as the pre-drilled sections of the effusion holes 27 covered bythe attached thermal barrier coating 34, as shown in FIGS. 11 and 14,may be conducted in order to accurately locate the positioned of thepre-drilled sections in the combustor component 28, thereby ensuringalignment of the pulse laser beam 42 with the pre-drilled section of theeffusion holes 37 in the following re-opening drilling step.

In FIG. 16, the effusion holes 37 (only one shown) in the combustorcomponent 28 are shown in a drilling procedure according to a furtherembodiment. The pulse laser beam 42 is set with a laser focal point 58located at the top surface 40 of the combustor component 28 in order toapply a first shot of the pulse laser beam 42 to strike the thermalbarrier coating 34 at a location of one of the effusion holes 37 in thecombustor component 28, thereby removing a volume of the thermal barriercoating material 34. Further shots of the pulse laser beam 42 areapplied to the location of this one effusion hole 37 to strike thethermal barrier coating 34 and/or bond coat (not indicated) to furtherremove the thermal barrier material and/or bond coat material, with thelaser focal point 58 being moved closer to the under surface 41 of thecombustor component 28 with each consecutive shot, as indicated by thearrow in FIG. 16. The process of drilling by applying shots of the pulselaser beam 42 with the laser focal point 58 being moved deeper into theeffusion hole 37 with each consecutive shot, may be conducted repeatedlyto complete the formation of this effusion hole 37 extending through thecombustor component 28. The remaining effusion holes 37 in the combustorcomponent 28 may be completed one after another in a similar procedureas described above.

Alternatively, the drilling procedure of by applying shots of the pulselaser beam 42 with the laser focal point 58 being moved deeper withinthe effusion hole 37 with each consecutive shot, may continue until asection of the effusion hole 37 extends through the thermal barriercoating 34 and the bond coat. The further drilling through the basemetal 30 may be conducted otherwise, for example by using the methodsdescribed in previous embodiments.

Referring to FIGS. 17 and 18, an assist gas jet such as pressurizednitrogen gas may be used in a laser drilling procedure, therebyfacilitating the laser drilling procedure. The assist gas jet, asindicated by arrows 60 is injected into the respective effusion holes 37being drilled during the pulse laser beam drilling procedure,substantially in the direction of the central axis 44 of the pulse laserbeam 42.

When a section of the effusion hole 37 is being drilled through thethermal barrier coating 34 and into the base metal 30, the assist gasjet 60 under high pressure and at high velocity will create a bendingmoment on the thermal barrier coating, as indicated by arrow 59 in FIG.17. This bending moment 59 may however cause substantial cracks in theinterface between the thermal barrier coating 34 and the base metal 30,resulting in TBC-BC spallation and/or BC-substrate spallation as shownin FIG. 2. The graphical illustration of FIG. 18 generally shows therelationship between the pressure of the assist gas jet (Assist GasPressure) which determines the velocity of the assist gas jetaccordingly and the bending moment (TBC Bending) acting on the thermalbarrier coating 34. Point A in the graphic illustration represents abending moment value of crack limit when the pressure of the assist gasjet reaches a target pressure. Crack occurrence begins when the bendingmoment value of crack limit is achieved. The target pressure value ofthe pressure of the assist gas jet according to an embodiment of thelaser drilling procedure, must be determined. The pressure of the assistgas jet is then adjusted such that the assist gas jet 60 is injectedinto the respective effusion holes 37 being drilled under a gas pressurewhich is lower than the determined target pressure value in order toavoid the occurrence of cracks in the interface between the thermalbarrier coating 34 and the base metal 30. The gas pressure of the assistgas jet 60 may be measured by a gas meter 62 at a gas jet nozzle 64which injects the assist gas jet 60.

Alternatively, the velocity of the assist gas jet 60 being injected intothe respective effusion holes 37, may be adjusted to be lower than apredetermined value corresponding to the target pressure value of theassist gas jet 60, for example lower than 100 psi, thereby limiting thebending moment 59 of the assist gas jet 60 acting on the thermal barriercoating 34 in order to avoid the occurrence of cracks in the interfacebetween the thermal barrier coating 34 and the base metal 30.

The embodiments of controlling an assist gas jet used in a laserdrilling procedure to avoid the occurrence of cracks between the thermalbarrier coating 34 and the base metal 30 are optionally combinable withany embodiments of the laser hole drilling procedures described in thepreviously described embodiments.

The described embodiments of the laser hole drilling procedure may becombined in any desired combinations to best fit into the manufacturingprocedures of various combustor components in different types of gasturbine engines, and need not be limited to the turbofan gas turbineengine as exemplarily illustrated in the drawings and described above.

The above description is meant to be exemplary only, and one skilled inthe art will recognize that changes may be made to the embodimentsdescribed without departure from the scope of the described subjectmatter. For example, cylindrical and truncated conical effusion holesare provided as examples to illustrate the principle of the laser holedrilling procedure according to various embodiments of the describedsubject matter. However, the described laser hole drilling procedures inthe various embodiments are applicable for drilling effusion holes invarious combustor components having a profile other than cylindrical ortruncated conical. The described laser hole drilling procedures in thevarious embodiments are also applicable for drilling effusion holes in acombustor component which has a thermal barrier coating coated directlyon a surface of a base metal without a bond coat therebetween. Thedescribed laser hole drilling procedures in the various embodiments arealso applicable to any components having a thermal barrier coating otherthan combustor components to drill shallow-angled holes therethrough.Still other modifications which fall within the scope of the describedsubject matter will be apparent to those skilled in the art, in light ofa review of this disclosure, and such modifications are intended to fallwithin the appended claims.

The invention claimed is:
 1. A method for providing a hole through ametal component having a base metal and a thermal barrier coatingapplied to the base metal to form a top surface of the component, themethod comprising: a) applying a pulse laser beam to the top surface ofthe component perpendicular with respect to the top surface to form asection of the hole substantially penetrating only the thermal barriercoating and leaving the base metal substantially intact, the section ofthe hole located within a boundary of a final perimeter of the hole; andthen b) changing an orientation of the pulse laser beam to an angle of20 degrees or less with respect to the top surface; and then c) applyingthe pulse laser beam with the changed orientation through the section ofthe hole partially formed in step (a) to drill through the thermalbarrier coating remaining within the boundary of the final perimeter ofthe hole and through the base metal to provide the final perimeter ofthe hole, the final perimeter of the hole defining opposed acute andobtuse angles of intersection with the top surface.
 2. The method asdefined in claim 1 wherein a depth of each perpendicular drilling instep (a) is not greater than a thickness of the thermal barrier coatinglocally at a location of the hole.
 3. The method as defined in claim 1wherein step (a) is conducted with a depth of each perpendiculardrilling free of damage to the final perimeter of the hole.
 4. Themethod as defined in claim 1 wherein in step (a) the pulse laser beam isset with a spot size smaller than a minimum cross-sectional dimension ofthe hole.
 5. The method as defined in claim 1 wherein step (a) isconducted by applying the pulse laser beam to more than one locationwithin the boundary of the final perimeter of the hole on the topsurface of the component, thereby reducing said residual thermal barriercoating material within the final perimeter of the hole.
 6. The methodas defined in claim 1 wherein the pulse laser beam is set with a firstpulse frequency rate in step (a) and is re-set with a second pulsefrequency rate in step (c), the first pulse frequency rate being higherthan the second pulse frequency rate.
 7. The method as defined in claim1 further comprising the steps of (i) determining a gas pressurecorresponding to a bending moment created by an assist gas jet on thethermal barrier coating just sufficient to create cracks between thethermal barrier coating and the base metal, and then (ii) injecting theassist gas jet into the hole being drilled during the pulse laser beamdrilling, with a pressure of the assist gas jet lower than 100 psi,thereby limiting a bending moment created by the assist gas jet notgreater than the determined pressure.
 8. The method as defined in claim1 wherein step (c) is conducted by applying shots of the pulse laserbeam to strike the base metal until the hole extends through thecomponent.
 9. The method as defined in claim 1 wherein the pulse laserbeam is set with a first pulse energy level in step (a) and is re-setwith a second pulse energy level in step (c), the first pulse energylevel being lower than the second pulse energy level.
 10. The method asdefined in claim 1 further comprising repeating steps (a), (b) and (c)to complete a plurality of holes extending through the component. 11.The method as defined in claim 10 comprising: determining a lowest gaspressure value at which injection of an assist gas jet into one of theholes being drilled during the pulse laser beam drilling initiates acrack occurrence in an interface between the thermal barrier coating andthe base metal; and injecting the assist gas jet under a gas pressureinto the respective holes being drilled during the pulse laser beamdrilling, the gas pressure being lower than the determined gas pressurevalue.
 12. The method as defined in claim 11 wherein the gas pressure ismeasured within a gas jet nozzle injecting the assist gas jet.